ABB Modures LZ91 Instructions For Installation And Operation Manual

ASEA BROWN BOVERI

CH-ES 83-92.10 E

Edition May

1991

modures®

Static Distance Relays

Types

L291

, L292, LZ92-1

Instructions for Installation

and

Operation

@1986ABB

Relays AG

Baden/Switzerland

4th edition

All rights with respect

to

this document, including applications for patent and registration

of

other industrial property rights, are reserved. Unauthorised use, in particular reproduc-

tion

or

making available

to

third parties,

is

prohibited.

This document has been carefully prepared and reviewed, however should in spite

of

this

the reader find an error, he is requested

to

inform us at his earliest convenience.

The data contained herein purports solely

to

describe the product and is not a warranty of

performance

or

characteristics. It is with the best interests of our customers in mind that

we constantly strive

to

improve

our

products and keep them abreast

of

advances in

technology. This may, however, lead

to

discrepancies between a product and its "Tech-

nical Description"

or

"Instructions

for

Installation and Operation".

C 0 N T E N T S

1.

2.

3.

3.1

3.1.1

3

.1.

2

3.1.3

3.2

3.2.1

3.2.2

3.3

3.4

3.4.1

3.4.2

3.5

3.6

3.7

3.8

3.9

3.10

3

.11

3.12

4.

5.

5.1

5.2

5.3

5.4

5.5

5.6

5.7

6.

6.1

6.2

6.3

6.4

6.5

6.6

6.7

7.

7.1

8.

9.

APPLICATION

MECHANICAL

DESIGN

DETERMINING

THE

SETTINGS

Selecting

the

operating

mode

Distance

relay

LZ91

Distance

relay

LZ92

Distance

relay

LZ92-l

Setting

the

starting

units

Overcurrent

starting

Underimpedance

starting

k

factor

for

the

distance

measuring

system

Igpedance

settings

of

the

various

zones

Determining

the

reaches

of

the

distance

zones

Determining

the

settings

m.

and

N.

• • J_

1.

Arc

resistance

compensation

Direction

of

measurement

Zone

4

Time

step

characteristic

Symbols

and

significance

of

the

switches

on

the

main

processing

unit

Main

processing

unit

equipped

for

intertripping

schemes

Frontplate

signals

Versions

of

the

input

transformer

and

main

processing

units

CHECKING

THE

SHIPMENT

INSTALLATION

AND

WIRING

Relay

location

and

ambient

conditions

Checking

the

wiring

C.t.

connections

P.t.

connections

Auxiliary

supply

Loading

of

tripping

and

signalling

contacts

Opto-coupler

inputs

COMMISSIONING

Checking

the

setting

prior

to

commissioning

Inserting

the

relay

and

switching

on

the

auxiliary

supply

Test

points

on

the

unit

EW91

Checking

the

load

voltages

and

currents

Testing

the

distance

relay

using

the

test

buttons

Testing

the

distance

relay

using

a

test

set

Instructions

for

modifying

relay

operation

OPERATION

AND

MAINTENANCE

Ancillaries

and~ares

TROUBLE-SHOOTING

APPENDICIES

Page

3

5

6

7

14

15

16

21

22

23

24

25

26

27

28

29

30

31

32

37

38

39

40

1

List

of

abreviations

and

symbols

I

Bmax

U,1

z.

1

Index

i

Index

p

Index

s

2

phase

currents

neutral

current

load

current

max.

load

current

possible

balancing

current

rated

current

fault

current

phase-to-neutral

voltages

ratio

of

zero

to

positive-sequence

impedances

(neutral

current

factor)

phase-angle

of

line

difference

voltage

(difference

between

fault

voltage

and

replica

impedance

voltage)

sum

voltage

(sum

of

fault

voltage

and

replica

impedance

voltage)

forwards

resp.

reverse

replica

reactances

of

the

underimpedance

starters

of

LZ92

or

LZ92-l

reactance

of

line

impedance

of

zone

i

positive-sequence

impedance

of

line

zero-sequence

impedance

of

line

zone

No.

primary

values

secondary

values

1.

APPLICATION

The

solid-state

distance

relays

LZ91, LZ92

and

LZ92-l

have

been

designed

for

high-speed

discriminative

protection

applications,

primarily

in

medium-voltage

systems.

They

are

equally

suitable

for

cable

and

overhead

line

circuits

and

the

power

systems

may

be

ungrounded,

impedance

or

solidly

grounded.

When

protecting

extremely

short

lines,

the

distance

relays

are

already

equipped

with

the

logic

to

operate

in

a

directional

comparison

scheme

(permissive

over-

reaching

transfer

tripping)

with

pilot

wires.

The

corresponding

pilot

wire

ancillaries

have

the

type

designations

ER91

and

NR91.

The

relays

are

also

prepared

for

operating

in

conjunction

with

an

auto-reclosure

relay

(e.g.

type

WT91

for

three-phase

reclosure).

All

the

relays

are

of

the

switched

type,

having

starting

units

(fault

detectors)

which

apply

the

correct

fault

quantities

to

a

single

direction

and

distance

determining

measuring

system.

The

starting

units

of

the

LZ91

operate

on

overcur-

rent,

so

that

the

relay

is

simpler

and

more

economical,

but

can

only

be

applied

in

systems

in

which

the

lowest

fault

current

is

clearly

greater

than

the

maximum

load

current.

Both

the

LZ92

and

the

LZ92-l

are

equipped

with

true

underimpedance

uni

ts

(not

just

voltage-controlled

overcurrent)

and

are

thus

capable

of

detec-

ting

weak

faults

at

times

of

low

generation

with

fault

currents

below

the

maximum

load

currents

at

peak

periods.

A

full

description

of

their

operation

is

contained

in

publication

CH-ES

23-92.lOE

"Solid-state

distance

relays

types

LZ91, LZ92

and

LZ92-l"

and

their

technical

data

is

given

in

data

Sheet

CH-ES

63-92.10

E.

2.

MECHANICAL

DESIGN

The

various

plug-in

units

which

make

up

the

relays

are

accommodated

in

standard

19"

electronic

equipment

racks,

and

these

in

turn

are

either

grouped

together

with

other

relays

in

cubicles,

or

fitted

into

casings

for

surface

or

semiflush

switchpanel

mounting.

The

corresponding

dimensioned

drawings

are

in

the

appendi-

ces

to

these

instructions.

The

plug-in

units

have

a

standard

height

of

3,5

U

(U

=

44.45

mm)

and

varying

widths

given

as

a number

of

divisions

T

(T

= 17 mm). One

19"

rack

has

space

for

plug-in

units

adding

up

to

a maximum

of

24

T.

The

standard

versions

of

the

distance

relays

LZ91, LZ92

and

LZ92-l

only

require

20

T,

which

is

less

than

one

full

rack.

The

distance

relays

comprise

the

following

plug-in

units:

-

input

transformer

unit

type

EW91,

width

6

T,

also

containing

signal

conditio-

ning

circuits,

measuring

sockets

and

auxiliary

tripping

relay.

-

main

processing

unit:

KI91

for

LZ91,

KZ91

for

LZ92

or

KZ91-l

for

LZ92-l.

The

terminals

of

the

main

processing

units

are

compatible

and

they

have

the

same

width.

3

4

-

signalling

unit

AV91

and/or

AV94

(1

T)

•

-

auxiliary

supply

unit

NF92 (3

T),

a

DC/DC

converter

for

generating

the

inter-

nal

relay

supply

voltages.

-

test

socket

connector

XX91

(option)

(3

T)

.

-

auto-reclosure

relay

WT91

(option)

(4

T).

-

pilot

wire

units

ER91

and

NR91

(option)

(4

Teach).

'rhese

instructions

apply

to

the

basic

versions

of

the

distance

relays,

i.e.

relays

equipped

with

EW91

and

either

KI91,

KZ91

or

KZ91-1

and

also

an

auxiliary

supply

unit.

There

are

two

versions

of

the

input

transformer

and

main

processing

units

available,

which

have

resulted

from

further

technical

develop-

ment

and

which

are

described

in

these

instructions

(see

Section

3.12).

3.

DETERMINING

THE

SETTINGS

All

important

settings

on

the

distance

relays

LZ91, LZ92

and

I,Z92-1

are

thumb-

wheel

switches.

The

corresponding

setting

formulas

are

printed

on

the

frontplate

(see

Figures

9.3

to

9.8).

In

each

case

the

setting

in

the

correct

dimensions

is

obtained

by

inserting

the

number

indicated

on

the

thumbwheel

switches

in

the

formula

and

working

it

out.

The

settings

themselves

(e.g.

impedance

of

the

under

impedance

starting

uni

ts)

are

printed

in

italics.

Settings

which

are

normally

only

made

once

during

commissioning

are

miniature

switches

located

on

the

PCB's.

Information

relating

to

these

settings

is

marked

on

the

frontplate

of

the

KI91,

KZ91

respectively

KZ91-l

behind

the

hinged

flap

of

the

equipment

rack

(Figures

9.

3

to

9.

8) . A

symbol

shows

on

which

PCB

the

particular

functional

switch

is

to

be

found.

The

PCB's

in

the

units

KI91,

KZ91

respectively

KZ91-1

are

numbered

from

left

to

right

seen

from

the

front

and

as

marked

on

the

frontplate.

(There

is

no

PCB

3

in

KI91.)

Further

information

on

this

can

be

found

in

Section

3.9.

3.1

Selecting

the

operating

mode

3.1.1

Distance

relay

LZ91

A

choice

can

be

made

between

two

operating

modes

using

miniature

switch

1

on

PCB

1

of

unit

KI91

(Fig.

9.21):

Mode

A

Mode L

for

solidly

grounded

systems,

i.e.

earth

faults

have

to

be

tripped.

for

ungrounded

or

impedance

grounded

systems,

but

only

with

acyclical

phase-preference

for

cross-country

faults.

3.1.2

Distance

relay

LZ92

As

with

the

distance

relay

LZ91, a

choice

can

be

made

between

the

modes A

and

L

using

miniature

switch

1

on

PCB

1

of

unit

KZ91.

In

this

case,

however,

mode

1::::,

also

permits

cyclical

(LO

in

the

code)

as

well

as

acyclical

(Ll

in

the

code)

phase-preference

for

cross-country

faults.

This

change

is

made

by

appro-

priately

positioning

soldered

link

LB7

on

PCB

1

(see

Fig.

9.22).

Standard

phase-preferences

are

R

before

T

before

S

(acyclically)

respectively

R

before

T,

T

before

S,

S

before

T

(cyclically).

3.1.3

Distance

relay

LZ92-l

In

solidly

grounded

systems

in

which

it

is

essential

that

earth

faults

be

tripped

mode

j;-

should

be

set.

In

ungrounded

or

impedance

grounded

systems

the

same

phase-preference

must

be

set

as

is

used

in

the

rest

of

the

system.

5

The

operating

mode

is

set

on

the

main

processing

unit

KZ91-1

with

the

aid

of

switch

1

(Fig.

9.23).

This

switch

has

four

sections

which

have

to

be

set

in

accordance

with

Table

3

.1.

'l'he same

information

is

printed

on

the

frontplate

behind

the

withdrawing

handle

(Fig.

9.8).

~·

switch

section

*

Mode

-

No.

1

No. 2 No.

3 No.

4

Phase

preference

Setting

OFF

ON

OFF

grounded

systems

±

OFF

ON

OFF

R'rS

acyclically

RTS

acyc.

ON

OFF OFF

RTSR

cyclically

R'l'SR

eye.

OFF

ON

OFF OFF

TRS

acyclically

TRS

acyc.

ON

OFF

OFF OFF

TRS'l'

cyclically

TRST

eye.

ON

OFF

ON

OFF

TSR

acyclically

TSR

acyc.

ON ON

ON

RST

acyclically

RST

acyc.

OFF

OFF OFF

OFF

STR

acyc

lie

ally

**

STR

acyc.

OFF

OFF OFF

ON

SRT

a<:Y_<:l_i_~~l

_

_1-y

**

SRT

acyc.

*

In

position

"ON"

the

white

lever

is

toward

the

PCB.

**

Only

for

units

with

the

designation

"AEND.

:B"

on

PCB

1.

Table

3.1

-

Positions

of

the

switch

sections

of

switch

1

on

PCB

1

of

unit

KZ91-1

in

relation

to

operating

mode

3.2

Setting

the

starting

units

3.2.1

Overcurrent

starting

6

The

pick-up

setting

of

the

overcurrent

uni

ts

must

be

at

the

very

least

so

high

that

it

cannot

be

reached

by

the

maximum

current

in

healthy

phases.

The

following

must

be

taken

into

account

when

calculating

this

current:

-

In

the

case

of

double-circuit

lines

the

load

current

can

briefly

double

when

one

line

is

tripped.

-

An

additional

balancing

current

IA

can

flow

in

the

healthy

phases

during

earth

faults.

A

relay

which

has

picked

up

must

also

be

able

to

reset

at

the

level

of

the

maximum

load

current

I

after

a

fault

has

been

tripped

in

the

first

zone

Bmax

.

of

another

relay.

Taking

the

reset

ratio

and

accuracy

of

the

relay

into

account,

the

lowest

permissible

setting

is

given

by:

lr;max

+~I

~~~~~~~-

+

0.06

The

maximum

pe.rmissible

setting

(I/I

)

is

calculated

from

the

minimum

fault

current

IK

for

a

fault

at

the

rerWo.r~xend

of

the

of

line.

(

Should

(I

/I

) .

be

less

than

(I/I

) .

according

to

the

above

relationship,

then

a

re!ayNwTtR

underimpendance

sW.a~E~ng,

e.g.

LZ92

or

LZ92-l,

must

be

used

instead

of

a

distance

relay

LZ91.

When

used

in

ungrounded

or

impedance

grounded

systems

(mode

L.

) ,

the

current

measuring

elements

of

unit

KI91

are

connected

to

R,

T

and

E.

The

sensitivity

of

the

neutral

element

in

the

standard

versions

is

twice

that

of

the

phase

elements

(I,r/IPh

=

0.5,

I/

•••

/

in

the

code

of

the

KI91).

If

some

other

sensitivity

is

specified,

it

can

be

seen

from

the

relay

ordering

code:

If

...

/sensitivity

factor

Should

it

be

impossible

to

set

the

phase

elements

such

that

they

pick

up

reliably

at

the

lowest

phase

fault

level,

but

do

not

pick

up

at

the

maximum

earth

fault

current,

then

a

distance

relay

LZ92

or

LZ92-1

must

be

used.

3.2.2

Underimpedance

starting

The

following

two

frontplate

(KZ91

or

KZ91-l)

settings

apply

to

the

underimpe-

dance

starting

units:

-

the

pick-up

of

the

neutral

current

element

-

the

reach

of

the

underimpedance

elements.

3.2.2.l

Neutral

current

earth

fault

detector

The

criterion

for

the

highest

setting

is:

- The

earth

fault

detector

must

pick

up

for

all

earth

faults

in

grounded

systems,

respectively

all

cross-country

faults

in

ungrounded

or

impedance

grounded

systems

which

lie

within

the

set

reach

of

the

underimpedance

units.

The

criterion

for

the

lowest

setting

is:

-

The

earth

fault

detector

may

not

pick

up

for

an

earth

fault

on

a

single

conductor

of

an

ungrounded

or

impdance

grounded

system.

-

The

earth

fault

detector

may

not

pick

up

during

heavy

phase

faults

due

to

spurious

neutral

currents

caused

by

c.t.

errors.

A

typically

recommended

value

is

I,r

(standard

version

of

the

LZ91:

I,r/IN

0.8

to

1.0

x

IN

for

LZ92

and

LZ92-l

0.

5)

•

If

there

is

no

setting

which

satisfies

both

these

limits,

a

neutral

voltage

polarising

ancillary

must

be

added

to

operate

in

conjunction

with

the

neutral

current

element:

-

This

is

available

as

a

separate

voltage

relay

to

be

inserted

into

the

equipment

rack

of

the

distance

relay.

7

-

Either

an

OR

or

an

AND

interlocking

logic

can

be

used

(see

parts

of

the

ordering

code

headed

EKl

or

EK2

in

the

tables

of

features

Table

9

.17,

Table

9.18

and

also

Fig.

9.25).

The

LED

signal

labelled

"E"

will

only

light

up

when

both

the

earth

fault

detector

and

at

least

one

underimpedance

phase

element

have

picked

up.

3.2.2.2

Reach

of

the

underimpedance

elements

8

standard

characteristic

The

standard

under

impedance

starting

characteristic

is

a

circle

with

its

centre

at

the

origin

of

the

impedance

plane.

The

relationships

for

an

earth

fault

R-0

are:

-

ULiR

-

Ul:R

-

·goo

--

UR

-

2

X

eJ

IR

A

-

j90

-

u +

2

XBe

IR

R

XA

=

XB

replica

reactance

in

forward

direction

replica

reactance

in

backward

direction

Criterion

for

pick-up:

u:R

j_

The

reach

for

radial

lines

and

the

different

kinds

of

faults

is:

-

phase-to-phase

fault:

same

as

setting

-

three-phase

fault

-

earth

fault

2

: x

setting

13

2

1 + k

oL

x

setting

(k = K

of

the

line)

oL o

ABB

has

a

computer

programme

for

checking

the

relay

settings

for

all

kinds

of

faults

and

fault

locations

where

complex

system

conditions

prevail.

The

starters

must

reliably

pick

up

for

a

fault

at

the

end

of

the

of

line

(back-up

zone).

Where

the

back-up

zone

is

not

being

taken

specifically

into

account,

the

setting

must

be

at

least

1.

3

times

the

impedance

of

the

protected

line.

The

influence

of

arc

resistance

must

also

be

considered

in

the

case

of

short

lines.

-

The

considerable

increase

of

load

current

which

can

occur

on

the

healthy

line

when

one

line

of

a

double

circuit

is

tripped

must

be

taken

into

account.

-

Balancing

currents

I

in

the

heal

thy

phases

during

an

earth

fault

must

not

cause

their

sta~ters

to

pick

up.

The

corresponding

limit

can

be

determined

as

follows:

1

B

max

·90°

2

X9

(IA+

19

max)

e J

Us

j900

-

XAe

-

2Is

-

'90°

U.t:.

A -

x

eJ

A

-

'90°

U.z.

.~

+ XBej90o

A +

X

eJ

B

-

2I

8

Fig.

3.2

-

Example

for

XA

f

XB

IA

I

Bmax

balancing

current

max.

load

current

replica

voltage

'90

I )

eJ

(S

phase)

Bmax

criterion

-

I_..

for

pick-up:

u.1

-L

Ur

--

·-+

'90°

--

u6

=

us

-

2

X

eJ

IS

A

·-

--

'90°

-

U,c:

us

+

2

X e

1

IS

B

___,...

- Us

with

A=

---

2

r;

The

limits

can

be

expressed

mathematically

as

follows:

-

in

grounded

systems

u

z

(Ohm/Phase)

9

-

in

ungrounded

or

impedance

grounded

systems

z

where

u

v

2 I x

1,25

Bmax

(Ohm/Phase)

U

lowest

phase-to-neutral

voltage

of

the

healthy

phases

for

an

earth

fault

(U

=

0.85

x

min.

rated

voltage)

U

lowest

phase-to-phase

rated

voltage

v

1.25

safety

factor

3.2.2.3

Special

underimpedance

starting

characteristics

10

If

it

is

impossible

to

satisfactorily

set

the

reach

according

to

Section

3.2.2.2,

then

the

following

procedure

should

be

tried.

The

influence

of

the

balancing

currents

must

be

carefully

analysed.

For

examining

the

S

phase

equations

for

an

R-0

earth

fault

see

Section

3.2.2.2.

The

relationship

XB/XA

may

be

changed

and

the

forward

reach

and

the

backward

reach

become

different.

The

origin

of

the

circular

characteristic

is

shifted

in

the

X-

direction.

( .

,,

A

I

B

The

diameter

of

circular

loci

of

the

pick-up

point

P

is

AB.

Fig.

3.3

-

Circular

underimpedance

starting

characteristic

The

angle

0

is

depending

on

the

network

conditions.

With

the

aid

of

computer

calculations

D was

found

to

be

2,

30°.

It

is

possible

to

change

the

angle.,C

from

90°

to

108°,

in

which

case

the

characteristic

is

no

longer

a

circle

(see

Fig.

3.4).

A

y

1

my

8

Fig.

3.4

-

Special

characteristic

o(

= 90°

or

108°

m

off-setting

factor

=

XB/XA

y =

permissible

setting

a

concentric

circle

11

12

Settings

t(O]

OU

0

J

m

'j

0

•••

90

1

30

90

0,57

1,04

30

108

1

1,18

(90)

(108)

(1)

(1,38)

30

108

0,57

1,22

Table

3.5

-

Permissible

settings

in

relation

to

a

circular

characteristic

Such

characteristics

have

a

considerably

extended

reactive

reach

compared

with

a

circle

concentric

to

the

origin.

The

equation

for

a

solidly

grounded

system

then

becomes:

u x y

=

where

1 + k

n =

----

0

-

for

starting

(Z///

..•

I

in

the

order

number)

2

-

It_J,s

pe~miss~ble

to

use

the

algebraic

sum

instead

of

the

geometric

sum (IA

+

IL),

since

it

represents

the

worst

case.

U

min.

phase-to-neutral

voltage

=

0.85

UB

.

(0.85

x

min.

rated

voltage)

min

The

effective

reach

along

the

line

is

dependent

on

the

characteristic

angle

of

the

line

and

the

kind

of

fault

(see

•rables

3.6

to

3.8):

-

Line

Characteristic

angle

Circle

Lense Lense

<pL

[ 0 ]

x = x

B A

XB

=

0.57

XA

x = x

B A

XB

=

0.57

XA

90

1

1 1

80

1 1

0.94

70

1

0.99

0.89

0.88

60

1

0.97

0.85

0.82

50

1

0.94

0.81

0.76

40

1

0.91

0.78

0.70

30

1

0.87

0.76

0.66

20

1

0.83

0.74

0.61

10

1

0.79

0.73

0.59

0

1

0.76 0.73

0.55

Lens:

ol

=

108°

(

Table

3.6

-

Relative

reach

in

relation

to

characteristic

and

line

angle

for

(."'

a

phase-to-phase

fault

Line

angle

90

80

70

60

50

40

30

20

10

0

1.15

Characteristic

Circle

XB

0,57

XA

1.11

1.08

1.04

1

0.94

0.92

0.87

0.83

0.79

0.75

0.98

0.94

0.89

0.88

0.85

0.84

0.83

0.85

0.88

Lense

XB

=

0,57

XA

0.95

0.88

0.82

0.76

0.72

0.67

0.64

0.61

0.59

0.58

Table

3.7

-

Relative

reach

in

relation

to

characteristic

and

line

angle

for

a

three-phase

fault

Line

angle

<p

[

0]

L

--

90

80

70

60

50

40

30

20

10

0

,__

(referred

to

the

reach

of

a

circle

about

the

origin

for

a

phase-to-phase

fault)

Characteristic

Circle Circle

Lense

XB

=

XA

XB

=

0,57

XA

XB

=

XA

XB

=

0,57

XA

-

1.15

1.11

0.98

0.95

1.15

1.08

1.0

0.94

1.15

1.06

1.0

0.93

1.15

1.04

1.03

0.93

1.15

1.02

1.05

0.95

1.15

1.01 1.08

0.97

1.15

1.0

1.11

0.98

1.15

1.0

1.12

1.0

1.15

1.0

1.16

1.02

1.15

1.0

1.21

1.05

·-

Table

3.8

-

Relative

reach

in

relation

to

characteristic

and

line

angle

for

a

three-phase

fault

(referred

to

the

reach

of

the

same

characteristic

for

a

phase-to-phase

fault)

13

Reverse

reach

The

effective

forwards

(XA)

and

reverse

(XB)

reaches

can

be

entered

in

the

diagram

of

Fig.

3.

2.

The

ratio

XB/XA

is

set

on

PCB

3

by

inserting

the

appropriate

value

for

resistor

Wi4

from

0.26

to

3.91

(Z./0.26/

to

/Z.3.91/

in

the

ordering

code,

see

Fig.

9.26).

Extreme

forwards

reaches

Values

of

XB/X

greater

than

1

are

of

consequence

when

an

extreme

forwards

reach

is

needefr.

This

is

achieved

by

reversing

the

primary

current

connec-

tions

to

the

distance

relay

and

then

reversing

the

measuring

direction

of

the

distance

unit

(using

switch

Sb

on

PCB

8,

order

number

HESG

439

686,

respectively

switch

I~

on

the

front

of

PCB

8,

HESG

440

718).

The

forwards

reach

then

corresponds

to

the

frontplate

setting

multiplied

by

the

set

ratio

XB/XA.

The

pick-up

criterion

in

the

diagram

of

Fig.

3.2

is

no

longer

determined

by

U,1

..L

u;,

but

instead

by

<f

(~,

lJi)

=

108°.

The

change

is

made

with

the

aid

of

the

soldered

link

LB3

on

PCB

3

(see

Fig.

9.26).

The

reach

for

earth

faults

corresponds

to

the

frontplate

setting

providing

the

k

factor

for

the

starting

units

matches

that

of

the

line

(k

= k

L).

The

s<Earter

k

is

set

using

resistor

Wi5

on

PCB

2

in

KZ91

or

K~~l-1

~see

0

Fig.

9.25).

The

above

changes

may

be

used

singly

or

in

conjunction

with

each

other!

3.3

k

factor

for

the

distance

measuring

system

-0

14

The

compensation

of

the

zero-sequence

impedance

is

calculated

from

the

positive-

sequence

impedance

ZL

and

zero-sequence

impedance

Z

of

the

line

or

cable.

oL

1

3

This

zero-sequence

compensation

factor

k

is

set

on

the

front

of

the

EW91

0

(according

to

HESG

438

454)

as

follows:

EW91

code

K.0:

Only

the

magnitude

of

(lk

I>

is

set.

This

is

generally

all

t.ha~

is

necessary

in

the

case

of

overhead

lines

(thumbwheel

switch

'Pk

set

to

zero).

0

EW91

code

K.1:

Both

the

magnitude

Clk

I)

and

phase-angle

('Pk )

are

set,

which

is

of

consequence

abov~

all

in

cable

systems.

0

It

is

always

possible

to

set

the

magnitude

and

phase-angle

in

the

case

of

the

input

transformer

unit

according

to

HESG

440 754

(see

Section

3.12).

The

k

factor

only

bears

an

influence

on

the

distance

measuring

system.

0

3.4

Impedance

settings

of

the

various

zones

3.4.1

Determining

the

reaches

of

the

distance

zones

In

order

to

calculate

the

settings

the

fault

impedances

and

the

phase-angles

of

the

sections

of

line

to

be

protected

must

be

known.

Z3

=

0,

BS

(a+

k ·

b2

l .

i-----

Z2

=

0,

85

(a

+ k ·

b1

l

-

b2

-

Z1

=0,85·0

-

I

-

~·--

Zus

= 1,2

I

b1

·a

I

A

-

a

-

b

-

B

(

Fig.

3.9

-

Reaches

of

the

various

distance

zones

a,

b

2

us

zone

impedances

infeed

factor

which

takes

into

account

an

intermediate

infeed

and

the

consequential

apparent

increase

in

the

impedance

by

the

relay

corresponding

line

impedances

overreach

zone

impedance

Zus

=

1.5

z

1

15

A

1

2

3

B

IA+

I B

4 -

(

0

Fig.

3.10

-

Exampel

for

the

calcuation

of

k;

k

where

check

the

overreach

for

k > 1

in

the

event

that

the

source

for

B

is

out

of

operation:

IA

+

IB

::::.

1

max.

possible

fault

current

min.

possible

fault

current

distance

relays

3.4.2

Determining

the

settings

m.

and

N.

1. 1.

16

z

Ls

where

ZLp

ZL

=--p-

-=:u_

rI

rz

primary

line

impedance

secondary

line

impedance

main

p.t.

ratio

main

c.

t.

ratio

impedance

ratio

The

secondary

resistance

and

reactance

values

are

calculated

in

the

same

manner.

Calculating

X.

-------------:'.!:

Before

the

values

m.

and

N.

can

be

set

on

the

main

processing

unit

it

is

necessary

to

calculal:e

the

feactances

X

..

These

are

not

exactly

equal

to

the

line

reactances

XL

(line

impedance

Z

=\

+

jXL),

because

of

the

inclination

of

the

relay

reactance

characteristi~

by

~he

angle

cl.

.

jX

R

x

=1

R

/X

=2

R

Fig.

3.11

-

Line

impedance

z

entered

in

the

relay

characteristic

L

Thus

to

obtain

the

reactances

X.,

the

line

reactances

have

to

be

corrected

by

l.

the

factor

kx:

The

correction

factor

kx

is

given

by:

tan

a

k

=l+"---

x

tan

<f>

If

the

phase-angle

V(_

is

less

than

40°,

as

can

be

the

case

in

cable

systems,

there

are

two

possibilities

for

grading

as

follows:

grading

in

relation

to

XL

grading

in

relation

to

RL

Grading

with

XL:

If

the

setting

R/X

is

greater

than

1,

e.g.

R/X

kx

according

to

the

table

3.12

is

used.

2

(see

Fig.

3.11),

then

the

factor

Grading

with

RL:

If

the

setting

of

the

polygon

is

made

in

relation

to

the

line

resistance

RL

with

the

arch

resistance

compensation

R/X = 1

(see

Section

3.5),

then

RLi

is

used

instead

of

XLi

and

kR

instead

of

kx

for

grading

(see

Table

3.12).

Where

for

ii

L <

40°:

Xi

=

kR

. RLi ;

with

kR

= 1 tancc'. .

tan

'f

17

18

Line

angle

R/X

=

I

R/X

=

2

sPL

( 0 )

_kx

k

R

kx

0

-

I

-

5

-

0,992

-

10

-

0,985

-

15

-

0,977

-

20

-

0,968

-

21

-

0,966

1,228

25

-

0,959

1,188

30

-

0,95

1,152

35

-

0,939

1,125

40

1,104

0,927

1,104

45

1,087

-

1,087

50

1,073

-

1,073

55

1,061

-

1,061

60

1,05

-

1,05

65

1,041

-

1,041

70

1,032

-

1,032

75

1,023

-

1,023

80

1,015

-

1,015

85

1,

008.

-

1,008

90

1

-

1

Table

3.12

-

Factors

kx

and

kR

in

relation

to

'P

(a=

5°)

System

voltage

P.

t.

ratio

C.t.

ratio

Primary

zone

impedances

Phase-angle

of

line

Relay

ratings

Reactance

line

slope

u

=

KU

KI

=

ZLpl

=

<p

IN

a

60

kV

(60

kV I

{J)

I

(110

v I

{3)

200

A I 5 A

40

4 Ohm,

ZLp2

=

6 Ohm,

z =

Lp3

60°

5

A,

UN

110

v

50

545.45

8

Ohm

Firstly

the

secondary

reactances

must

be

calculated

from

the

primary

values:

ii

I

X .

x--and

Lp

..

uu

The

line

reactances

for

the

three

zones

become:

XLl

=

0.254

Ohm,

XL

2

0.381

Ohm,

xL

3

=

0.508

Ohm

The

correct.ion

factor

kx

is:

tan

5°

1 + =

1.05

tan

60°

(

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